CN212535928U

CN212535928U - Wind power generator

Info

Publication number: CN212535928U
Application number: CN202021802069.3U
Authority: CN
Inventors: 罗来欢
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-08-26
Filing date: 2020-08-26
Publication date: 2021-02-12
Anticipated expiration: 2030-08-26

Abstract

The utility model discloses a wind power generation device, include upper plate, hypoplastron and be located the impeller between upper plate, the hypoplastron, the relative parallel arrangement of upper plate and hypoplastron, be equipped with a plurality of impellers between upper plate and the hypoplastron, the impeller is arranged into two, and each impeller of being listed as passes through drive mechanism and connects, realizes synchronous rotation, two are listed as impeller place planes and form a contained angle, contained angle department is equipped with the aviation baffle, two are listed as impeller apart from the nearest impeller of aviation baffle and are first power impeller and second power impeller respectively, be equipped with the interlock structure between first power impeller and the second power impeller, be connected with the generator on the first power impeller. The utility model utilizes the impeller to convert wind power into kinetic energy, and the kinetic energy is transmitted on the generator through the design of a plurality of gears, thereby realizing wind power generation; the device can be applied to the sea surface or the land, and the purpose of generating power in different environments is achieved by matching with different fixing structures.

Description

Wind power generator

Technical Field

The utility model belongs to the technical field of wind power generation, especially, relate to a wind power generation set.

Background

Wind energy is more and more concerned as a clean and pollution-free renewable energy source, and wind power generation becomes one of new energy sources developed on the largest scale in the 21 st century. A wind power generator is an electric power device that converts wind energy into mechanical energy, and converts the mechanical energy into electric energy. In a broad sense, the heat energy utilization engine takes the sun as a heat source and takes the atmosphere as a working medium. The largest defects of the existing wind power generator are large occupied area and single direction, the wind power collection efficiency is lower for the changeable wind direction in one day, the application environment of the existing wind power generation device is single, the existing wind power generation device cannot be synchronously applied to the sea surface or the land, and the application range is reduced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a wind power generation device, this power generation facility simple structure can change the device size according to the demand, can use on sea or land, through the different fixed knot structure of cooperation, makes it reach the purpose of electricity generation under different environment.

In order to achieve the above purpose, the utility model adopts the technical scheme that: a wind power generation device comprises an upper plate, a lower plate and impellers positioned between the upper plate and the lower plate, wherein the upper plate and the lower plate are arranged in parallel relatively, a plurality of impellers are arranged between the upper plate and the lower plate and are arranged in two rows, each row of impellers are connected through a transmission mechanism to realize synchronous rotation, an included angle is formed between the planes of the two rows of impellers, an air deflector is arranged at the included angle, the impellers, closest to the air deflector, of the two rows of impellers are a first power impeller and a second power impeller respectively, a linkage structure is arranged between the first power impeller and the second power impeller, and a generator is connected to the linkage structure.

The technical scheme of further improvement in the technical scheme is as follows:

1. in the above scheme, the impeller comprises a central shaft, a sleeve and blades, two ends of the central shaft are respectively connected to the upper plate and the lower plate, the sleeve is fixed on the outer side of the central shaft, and a plurality of blades are arranged on the outer side of the sleeve.

2. In the above scheme, the transmission mechanism of each row of impellers is a plurality of gears which are meshed together and is divided into an upper gear and a lower gear, the upper gear is installed on the outer side of the upper end of the central shaft, one side of the upper gear abuts against the upper plate, an upper partition plate is arranged on one side of the upper gear, which is opposite to the upper plate, and the upper gear is positioned between the upper plate and the upper partition plate; the lower gear is arranged on the outer side of the lower end of the central shaft, one side of the lower gear abuts against the lower plate, a lower partition plate is arranged on the side, opposite to the lower plate, of the lower gear, and the lower gear is located between the lower plate and the lower partition plate.

3. In the scheme, an upper transition gear and a lower transition gear are arranged between two adjacent central shafts, the upper transition gear is positioned between two adjacent upper gears, and the upper transition gear is fixed between an upper plate and an upper partition plate through a short shaft; the lower transition gear is positioned between two adjacent lower gears and is fixed between the lower plate and the lower partition plate through a short shaft.

4. In the above scheme, the linkage structure between the first power impeller and the second power impeller is a first power gear and a second power gear which are meshed with each other, the first power gear is arranged on a central shaft of the first power impeller, the second power gear is arranged on a central shaft of the second power impeller, and the first power gear and the second power gear are both arranged close to the lower gear and are positioned on one side of the lower partition plate, which is opposite to the lower gear.

5. In the above scheme, the first power impeller transmits power to the generator through a first bevel gear and a second bevel gear which are matched with each other, the first bevel gear is mounted on a central shaft of the first power impeller, the first bevel gear is meshed with the second bevel gear, and the generator is connected with the second bevel gear through a transmission shaft.

6. In the above scheme, the transmission mechanism of each row of impellers comprises a plurality of steering gears connected together, each steering gear comprises a gear box and a first steering bevel gear and a second steering bevel gear which are positioned inside the gear box, and the first steering bevel gear and the second steering bevel gear are in meshed connection; the upper surfaces of the upper plate and the lower plate are respectively provided with two rows of steering gears along the distribution direction of two rows of impellers, each row of steering gears are connected together through a steering shaft, a first steering bevel gear in each steering gear is fixedly connected to the end part of a central shaft of the corresponding impeller, a second steering bevel gear is connected to the steering shaft, and when the impellers rotate, the central shaft and the first steering bevel gear synchronously rotate and simultaneously drive the second steering bevel gear to rotate;

the steering device comprises an upper plate, a lower plate, a steering shaft, a steering device and a bracket, wherein the upper plate and the lower plate are fixedly connected with an upper partition plate and a lower partition plate respectively, the upper partition plate and the lower partition plate are installed on the upper plate and the lower plate through the bracket, the steering device and the steering shaft installed on the upper surface of the upper plate are located between the upper plate and the upper partition plate, and the steering device and the steering shaft installed on the upper surface of the lower plate are located between the lower plate and the lower partition.

7. In the above scheme, the linkage structure between the first power impeller and the second power impeller comprises a transmission shaft and third steering bevel gears, the inside of a steering gear connected below the first power impeller and the second power impeller is respectively provided with one third steering bevel gear, the two third steering bevel gears are respectively in toothed connection with the first steering bevel gears in the two steering gears, a transmission shaft is arranged between the two third steering bevel gears, when the third steering bevel gears rotate, the transmission shafts synchronously rotate, the middle part of the transmission shaft is provided with one steering gear, and the generator is connected to the steering gear; the first steering bevel gear of the steering gear is arranged on the transmission shaft, and the second steering bevel gear is connected with the generator

8. In the scheme, bearings are arranged at the joints of the central shaft and the upper plate, the lower plate, the upper partition plate and the lower partition plate, and the short shaft is respectively connected with the joints of the upper plate, the lower plate, the upper partition plate and the lower partition plate through the bearings;

bearings are adopted among the central shaft, the transmission shaft, the steering shaft and the gear box.

9. In the scheme, the upper plate and the lower plate are triangular plates with the same direction, the two rows of impellers are distributed along two bevel edges of the triangular plates, the air guide plate is arranged at an included angle of the two rows of impellers, the included angle of the two rows of impellers is 50-60 degrees, two sides of the air guide plate are respectively parallel to planes of the two rows of impellers, and the upper end and the lower end of the air guide plate are respectively fixed on the upper plate and the lower plate.

10. In the above scheme, when the wind power generation device is used on land, the wind power generation device further comprises a fixing device, wherein the fixing device comprises an empennage, a base, a support shaft, a first support seat and a second support seat, the first support seat is installed on the lower surface of the upper plate, the second support seat is installed on the lower surface of the lower plate, the first support seat and the second support seat are in up-and-down correspondence in position, the first support seat and the second support seat are connected through a support shaft penetrating through the lower plate, the lower end of the support shaft is fixed on the base, the support shaft is arranged on a connecting line of the center of gravity of the wind power generation device and the end part of the air deflector, and bearings are arranged at the connecting parts of the support shaft, the first support seat and; the empennage is arranged on the upper surface of the upper plate, is arranged between the two rows of impellers and is distributed along the symmetrical shafts of the two rows of impellers, and the tail end of the empennage extends to the outer side of the upper plate.

11. In the above scheme, when the wind power generation device is used on the sea surface, the wind power generation device further comprises a floating device, a fixing pile and a rope, the lower plate is fixed on the floating device, the floating device floats on the water surface, one end of the floating device is connected to the fixing pile through the rope, the fixing pile is fixed under water, and the connecting end of the rope and the floating device is opposite to the tip end of the air deflector.

12. In the scheme, the wind power generation device can be provided with a multilayer structure, and a generator is arranged in each layer of structure, so that wind energy can be better collected, and the power generation efficiency is improved.

13. In the above scheme, the floating device is a ship.

14. In the above scheme, the blades may be plane blades or arc blades.

Because of above-mentioned technical scheme's application, compared with the prior art, the utility model have the following advantage:

1. the utility model discloses a wind power generation device, it utilizes the impeller to convert wind-force into kinetic energy, through the design of a plurality of gears, transmits kinetic energy on the generator, realizes wind power generation; the device has a simple structure, can change the size of the device according to requirements, can be applied to the sea or the land, and achieves the purpose of generating power under different environments by matching with different fixing structures.

2. The utility model discloses wind power generation set, it sets up the aviation baffle, can guide wind, makes the wind direction become the V type and removes, then sets up the impeller into two rows, is the V style of calligraphy, just corresponds the wind through the aviation baffle, and wind drives the impeller and rotates, converts wind energy into kinetic energy; the impellers are in transmission connection through a gear or a steering gear, so that the transmission of kinetic energy is realized, and the overall structure is lighter when the steering gear is adopted.

3. The utility model discloses wind power generation set, it sets up the aviation baffle and is listed as the impeller, is divided into two with wind energy, can improve the utilization ratio of wind energy, improves the generating efficiency.

4. The utility model discloses wind power generation set, it is when generating electricity on land, cooperate the fixing device to use, can change the direction at any time, make it unanimous with the wind direction from beginning to end, improve the generating efficiency; meanwhile, when power is generated on the sea surface, the floating device is used in a matched mode, the direction of the device can be changed along with the wind direction, and the use of the wind power generation device under different wind directions is met.

Drawings

Fig. 1 is a schematic structural diagram of embodiment 1 of the present invention.

Fig. 2 is a cross-sectional view of embodiment 1 of the present invention.

Fig. 3 is a schematic view of the installation of the generator according to embodiment 1 of the present invention.

Fig. 4 is a schematic view of an installation structure of the first bevel gear and the second bevel gear in embodiment 1 of the present invention.

Fig. 5 is a schematic structural view of a single impeller in embodiment 1 of the present invention.

Fig. 6 is a schematic view of the connection between the stub shaft and the transition gear according to embodiment 1 of the present invention.

Fig. 7 is a schematic structural diagram of embodiment 1 of the present invention.

Fig. 8 is a schematic structural view of a fixing device according to embodiment 1 of the present invention.

Fig. 9 is a schematic structural diagram of embodiment 2 of the present invention.

Fig. 10 is a schematic diagram of two rows of included angles between the impellers according to the present invention.

Fig. 11 is a schematic structural diagram of embodiment 3 of the present invention.

Fig. 12 is a schematic structural diagram of a power generation device according to

embodiments

3 and 4 of the present invention.

Fig. 13 is a left side view of the power generation device according to

embodiments

3 and 4 of the present invention.

Fig. 14 is a schematic diagram of the installation of the generator according to

embodiments

3 and 4 of the present invention.

In the figure: 1. an upper plate; 2. a lower plate; 3. an air deflector; 4. a generator; 5. a first powered impeller; 6. a second powered impeller; 7. a central shaft; 8. a sleeve; 9. a blade; 10. an upper gear; 11. an upper partition plate; 12. a lower gear; 13. a lower partition plate; 14. an upper transition gear; 15. a lower transition gear; 16. a minor axis; 17. a first power gear; 18. a second power gear; 19. a first bevel gear; 20. a second bevel gear; 21. a tail wing; 22. a base; 23. a support shaft; 24. a first support base; 25. a second support seat; 26. a floatation device; 27. fixing the pile; 28. a rope; 29. a bearing; 30. a diverter; 31. a steering shaft; 32. a first steering bevel gear; 33. a second steering bevel gear; 34. a bevel gear box; 35. a drive shaft; 36. and a third steering bevel gear.

Detailed Description

In the description of this patent, it is noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention; the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; furthermore, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, as they may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The meaning of the above terms in this patent may be specifically understood by those of ordinary skill in the art.

The invention will be further described with reference to the following examples:

example 1: as shown in fig. 1 to 6, a wind power generation device comprises an upper plate 1, a lower plate 2 and impellers arranged between the upper plate 1 and the lower plate 2, wherein the upper plate 1 and the lower plate 2 are two triangular plates with the same size and direction and are arranged in parallel relatively, a plurality of impellers are arranged between the upper plate 1 and the lower plate 2, the impellers are arranged in two rows, the impellers in the two rows are distributed along two bevel edges of the triangular plates, each row of impellers are connected through a transmission mechanism to realize synchronous rotation, an air guide plate 3 is arranged at an included angle of the impellers in the two rows, as shown in fig. 10, the included angle a of the impellers in the two rows is 55 degrees, two sides of the impeller in the two rows are respectively parallel to a plane where the impellers in the two rows are located, the upper end and the lower end of the air guide plate 3 are respectively fixed on the upper plate 1 and the lower plate 2, when wind blows from the tip end side of the air guide plate 3, the air, driving the impeller on the side surface to rotate;

the impeller includes center pin 7, sleeve pipe 8 and

blade

9, 7 both ends of center pin are connected respectively on upper plate 1 and hypoplastron 2, and sleeve pipe 8 is fixed in the 7 outsides of center pin, the 8 outsides of sleeve pipe are equipped with a plurality of blades 9, blade 9 can set up to straight board, also can be the arc of taking the radian, and blade 9 is fixed connection with sleeve pipe 8 and center pin 9, and when blade 9 rotated, sleeve pipe 8 rotated with center pin 9 together.

The transmission mechanism of each row of impellers is a plurality of gears which are meshed together and is divided into an upper gear 10 and a lower gear 12, the upper gear 10 is installed on the outer side of the upper end of the central shaft 7, one side of the upper gear 10 is abutted against the upper plate 1, an upper partition plate 11 is arranged on one side, opposite to the upper plate 1, of the upper gear 10, and the upper gear 10 is located between the upper plate 1 and the upper partition plate 11; the lower gear 12 is arranged on the outer side of the lower end of the central shaft 7, one side of the lower gear 12 is close to the lower plate 2, a lower partition plate 13 is arranged on the side, opposite to the lower plate 2, of the lower gear 12, and the lower gear 12 is positioned between the lower plate 2 and the lower partition plate 13; an upper transition gear 14 and a lower transition gear 15 are arranged between two adjacent central shafts 7, the upper transition gear 14 is positioned between two adjacent upper gears 10, and the upper transition gear 14 is fixed between the upper plate 1 and the upper partition plate 11 through a short shaft 16; the lower transition gear 15 is positioned between two adjacent lower gears 12, and the lower transition gear 15 is fixed between the lower plate 2 and the lower partition plate 13 through a stub shaft 16; the joints of the central shaft 7 and the upper plate 1, the lower plate 2, the upper partition plate 11 and the lower partition plate 13 are all provided with bearings 29, and the short shaft 16 is respectively connected with the joints of the upper plate 1, the lower plate 2, the upper partition plate 11 and the lower partition plate 13 through the bearings 29; when wind blows, the blades 9 rotate to drive the sleeve 8 to rotate synchronously with the central shaft 7, bearings 29 are arranged at the joints of the central shaft 9, the upper plate 1, the lower plate 2, the upper partition plate 11 and the lower partition plate 13, so that the rotation is not influenced, the upper gear 10 and the lower gear 12 on the central shaft 7 are fixedly connected with the central shaft 7, so that the rotation is synchronous, and the upper transition gear 14 and the lower transition gear 15 are arranged, so that the impellers can rotate together, and finally, power can be transmitted to the gear closest to the air deflector 3.

The impellers of the two rows of impellers closest to the air deflector 3 are respectively a first power impeller 5 and a second power impeller 6, a linkage structure is arranged between the first power impeller 5 and the second power impeller 6, the linkage structure between the first power impeller 5 and the second power impeller 6 is a first power gear 17 and a second power gear 18 which are meshed with each other, the first power gear 17 is arranged on a central shaft 7 of the first power impeller 5, the second power gear 18 is arranged on the central shaft 7 of the second power impeller 6, the first power gear 17 and the second power gear 18 are both arranged close to the lower gear 12 and are positioned on one side of the lower partition plate 13 opposite to the lower gear 12, the first power gear 17 and the second power gear 18 are meshed and connected, the power of the two rows of impellers can be concentrated on the first power gear 17 or the second power gear 18, and the first power gear 17 or the second power gear 18 is connected with the generator 4, the impeller power is converted into electricity, where the generator 4 is connected to the first power gear 17;

the first power impeller 5 transmits power to the generator 4 through a first bevel gear 19 and a second bevel gear 20 which are matched, the first bevel gear 19 is arranged on the central shaft 7 of the first power impeller 5, the first bevel gear 19 is in meshed connection with the second bevel gear 20, and the generator 4 is connected with the second bevel gear 20 through a transmission shaft; when wind blows, the impellers rotate, the first power gear 17 and the second power gear 18 gather the power of the two rows of impellers on the first power gear 17, when the first power gear 17 rotates, the first bevel gear 19 on the central shaft 7 rotates synchronously, and the power of the impellers is transmitted to the generator 4 through the meshed second bevel gear 20.

When the wind power generation device is used, the direction of the wind power generation device needs to be adjusted to the state that the tip end of the wind deflector 3 is opposite to the wind direction, so that the maximum utilization of wind energy can be realized.

As shown in fig. 7 to 8, when the wind power generator is applied to land, it needs to be fixed on the ground by a fixing device, the fixing device includes a tail fin 21, a base 22, a supporting shaft 23, a first supporting seat 24 and a second supporting seat 25, the first supporting seat 24 is installed on the lower surface of the upper plate 1, the second supporting seat 25 is installed on the lower surface of the lower plate 2, the positions of the first supporting seat 24 and the second supporting seat 25 correspond up and down, the first supporting seat 24 and the second supporting seat 25 are connected by a supporting shaft 23 penetrating through the lower plate 2, the lower end of the supporting shaft 23 is fixed on the base 22, bearings 29 are respectively arranged at the joints of the supporting shaft 23, the first supporting seat 24 and the second supporting seat 25, so that the wind power generator can rotate around the supporting shaft 23 and the base 22, and the wind direction of the wind power generator is consistent when the wind power generator is applied; the tail wing 21 is arranged on the upper surface of the upper plate 1 and is arranged between two rows of impellers and distributed along the symmetrical axes of the two rows of impellers, the tail end of the tail wing 21 extends to the outer side of the upper plate 1, the tail wing 21 is arranged for timely adjusting the position of the wind power generation device, when a certain angle exists between the wind direction and the tail wing 21, the wind power generation device rotates along the supporting shaft 23 under the action of wind power, and meanwhile, as the supporting shaft 23 is arranged on the connecting line of the gravity center of the wind power generation device and the end part of the wind deflector 3, namely the gravity center of the wind power generation device is positioned at the rear side of the supporting shaft 23, the end part of the wind deflector 3 faces the wind blowing side in the rotating process of the wind power generation device along the supporting.

When the wind power generation device is used, the base 22 is fixed on a horizontal plane, the wind power generation device is installed on the base 22, when wind blows, the tail wing acts to drive the wind power generation device to rotate, the end part of the wind deflector 3 faces a wind blowing position, at the moment, the wind deflector 3 guides the wind to two side surfaces, the wind blows to impellers on two sides, the impellers transmit power through gears in the rotating process, a first power gear 17 and a first bevel gear 19 are arranged on a central shaft 7 where a lower gear 12 closest to the wind deflector is located, the first power gear 17 converges the power of the impeller on the other side on a first power impeller 5, and the first bevel gear 19 transmits the finally converged power to the generator 4 to realize power generation.

Example 2: the structure of the wind power generation device is the same as that of the embodiment 1, but the application is different, and the wind power generation device is used on the sea surface to generate power in the embodiment;

as shown in fig. 9, when the wind power generating device is used on the sea surface, the wind power generating device comprises a floating device 26, a fixing pile 27 and a rope 28, the lower plate 2 of the wind power generating device is fixed on the floating device 26, the floating device 26 floats on the sea surface, one end of the floating device 26 is connected to the fixing pile 27 through the rope 28, the fixing pile 27 is fixed in the sea, the connecting end of the rope 28 and the floating device 26 is opposite to the tip end of the wind deflector 3, when wind blows, the floating device 26 rotates along the fixing pile under the traction of the rope 28 until the floating device 26 and the rope 28 keep the same wind direction, as the connecting end of the rope 28 and the floating device 26 is opposite to the tip end of the wind deflector 3, the wind direction is opposite to the tip end of the wind deflector 3, the wind deflector 3 guides the wind to two sides, the wind blows to the impellers on two sides, the impellers transmit power through gears during the rotation, wherein, a first power gear 17 and a first bevel gear 19 are arranged on the central shaft 7 where the lower gear 12 closest to the air deflector is positioned, wherein the first power gear 17 converges the power of the impeller on the other side on the first power impeller 5, and the first bevel gear 19 transmits the finally converged power to the generator 4 to realize power generation.

The floating device 26 is often a ship, and when in use, the wind deflector 3 of the wind power generator is aligned with the direction of the bow of the ship, and the rope 28 is fixedly connected to the bow of the ship.

The above-mentioned contents of the present invention are further explained as follows:

the utility model discloses a wind power generation device, it utilizes the impeller to convert wind-force into kinetic energy, through the design of a plurality of gears, transmits kinetic energy on the generator, realizes wind power generation; the device has a simple structure, can change the size of the device according to requirements, can be applied to the sea or the land, and achieves the purpose of generating power under different environments by matching with different fixing structures.

In addition, the wind deflector is arranged to guide wind to change the wind direction into V-shaped movement, then the impellers are arranged into two rows in a V shape, the wind drives the impellers to rotate just corresponding to the wind passing through the wind deflector, and the wind energy is converted into kinetic energy; then the upper end and the lower end of each impeller are provided with gears, and a transition gear is arranged between adjacent gears, so that all the impellers can synchronously rotate, and the transmission of power among the impellers is also realized; meanwhile, two rows of impellers are provided with two meshed power gears at the convergence position of the V-shaped end, so that the kinetic energy of the impellers at two sides can be converged, and finally, the kinetic energy is transmitted to the generator through a group of bevel gears, and the conversion from the kinetic energy to the electric energy is realized.

In addition, when the wind power generation device is used for generating power on land, the direction can be changed at any time by matching with the fixing device, so that the wind power generation device is consistent with the wind direction from beginning to end, and the power generation efficiency is improved; meanwhile, when power is generated on the sea surface, the floating device is used in a matched mode, the direction of the device can be changed along with the wind direction, and the use of the wind power generation device under different wind directions is met.

Example 3: as shown in fig. 10 to 14, a wind power generation device comprises an upper plate 1, a lower plate 2 and impellers arranged between the upper plate 1 and the lower plate 2, wherein the upper plate 1 and the lower plate 2 are two triangular plates with the same size and direction and are arranged in parallel relatively, a plurality of impellers are arranged between the upper plate 1 and the lower plate 2, the impellers are arranged in two rows, the impellers in the two rows are distributed along two bevel edges of the triangular plates, each row of impellers are connected through a transmission mechanism to realize synchronous rotation, a wind guide plate 3 is arranged at an included angle of the impellers in the two rows, as shown in fig. 10, an included angle a of the impellers in the two rows is 50 degrees, two sides of the impellers are respectively parallel to planes of the impellers in the two rows, the upper end and the lower end of the wind guide plate 3 are respectively fixed on the upper plate 1 and the lower plate 2, when wind blows from the tip end side of the wind guide plate 3, the wind guide plate 3 can shield the wind to, driving the impeller on the side surface to rotate;

the impeller includes center pin 7, sleeve pipe 8 and

blade

The transmission mechanism of each row of impellers comprises a plurality of steering gears 30 which are connected together, two rows of steering gears 30 are respectively arranged on the upper surfaces of the upper plate 1 and the lower plate 2 along the distribution direction of the two rows of impellers, namely, the upper end and the lower end of each impeller are respectively provided with one steering gear 30, the steering gears 30 on the upper side and the lower side of each row of impellers are respectively connected together through a steering shaft 31, each steering gear 30 comprises a gear box 34 and a first steering bevel gear 32 and a second steering bevel gear 33 which are positioned in the gear box 34, and the first steering bevel gear 32 is meshed with the second steering bevel gear 33; the first steering bevel gear 32 in each steering gear 30 is fixedly connected with the end part of the corresponding impeller central shaft 7, when the central shaft 7 rotates, the first steering bevel gears 32 at the two ends synchronously rotate and rotate together through the second steering bevel gears 33 which are connected in a meshing way, the second steering bevel gears 33 are connected on the steering shaft 31, when the second steering bevel gears 33 rotate, the steering shaft 31 rotates together, and the connecting part of the steering shaft 31 and the gear box 34 is provided with a bearing;

the upper surfaces of the upper plate 1 and the lower plate 2 are respectively fixedly connected with an upper partition plate 11 and a lower partition plate 13, wherein the upper partition plate 11 and the lower partition plate 13 are respectively installed on the upper plate 1 and the lower plate 2 through a bracket or other fixing structures, spaces capable of accommodating the steering gear 30 are formed between the upper partition plate 11 and the upper plate 1 and between the lower partition plate 13 and the lower plate 2, the steering gear 30 and the steering shaft 31 installed on the upper surface of the upper plate 1 are located between the upper plate 1 and the upper partition plate 11, the steering gear 30 and the steering shaft 31 installed on the upper surface of the lower plate 2 are located between the lower plate 2 and the lower partition plate 13, the upper end and the lower end of the central shaft 7 are connected with the upper partition plate 11 and the lower partition plate 13 through bearings, and the upper partition plate 11 and the lower partition plate 13 are arranged.

The linkage structure between the first power impeller 5 and the second power impeller 6 comprises a transmission shaft 35 and a third steering bevel gear 36, when the impellers rotate, the first steering bevel gears 32 at the two ends of the impellers synchronously rotate, and the steering shaft 31 rotates through the transmission of the second steering bevel gear 33, so that when wind blows, whichever impeller rotates finally drives the first power impeller 5 and the second power impeller 6 to rotate; a third steering bevel gear 36 is respectively arranged in the steering gears 30 connected below the first power impeller 5 and the second power impeller 6, the two third steering bevel gears 36 are respectively in toothed connection with the first steering bevel gears 32 in the two steering gears 30, when the first power impeller 5 and the second power impeller 6 rotate, the first steering bevel gears 32 can drive the third steering bevel gears 36 to rotate, a transmission shaft 35 is arranged between the two third steering bevel gears 36, and when the third steering bevel gears 36 rotate, the transmission shaft 35 synchronously rotates; the middle part of the transmission shaft 35 is provided with a steering gear 30, and the generator 4 is connected to the steering gear 30; the first steering bevel gear 32 of the steering gear 30 is mounted on the transmission shaft 35, the second steering bevel gear 33 is connected with the generator 4, when the transmission shaft 35 rotates, the first steering bevel gear 32 on the transmission shaft 35 rotates synchronously, and the generated kinetic energy is transmitted to the generator 4 by driving the second steering bevel gear 33 to rotate.

As shown in fig. 11, when the wind power generator is applied to land, it needs to be fixed on the ground by a fixing device, the fixing device includes a tail fin 21, a base 22, a supporting shaft 23, a first supporting seat 24 and a second supporting seat 25, the first supporting seat 24 is installed on the lower surface of the upper plate 1, the second supporting seat 25 is installed on the lower surface of the lower plate 2, the first supporting seat 24 and the second supporting seat 25 are vertically corresponding in position, the first supporting seat 24 and the second supporting seat 25 are connected by a supporting shaft 23 penetrating through the lower plate 2, the lower end of the supporting shaft 23 is fixed on the base 22, and bearings 29 are respectively arranged at the joints of the supporting shaft 23, the first supporting seat 24 and the second supporting seat 25, so that the wind power generator can rotate around the supporting shaft 23 and the base 22, and the wind power generator is aligned with the wind direction when the wind power generator is applied; the tail wing 21 is arranged on the upper surface of the upper plate 1 and is arranged between two rows of impellers and distributed along the symmetrical axes of the two rows of impellers, the tail end of the tail wing 21 extends to the outer side of the upper plate 1, the tail wing 21 is arranged for timely adjusting the position of the wind power generation device, when a certain angle exists between the wind direction and the tail wing 21, the wind power generation device rotates along the supporting shaft 23 under the action of wind power, and meanwhile, as the supporting shaft 23 is arranged on the connecting line of the gravity center of the wind power generation device and the end part of the wind deflector 3, namely the gravity center of the wind power generation device is positioned at the rear side of the supporting shaft 23, the end part of the wind deflector 3 faces the wind blowing side in the rotating process of the wind power generation device along the supporting.

When the wind power generation device is used, the base 22 is fixed on a horizontal plane, the wind power generation device is installed on the base 22, when wind blows, the tail wing acts to drive the wind power generation device to rotate, the end part of the wind deflector 3 faces the wind blowing position, at the moment, the wind deflector 3 guides the wind to two side surfaces, the wind blows to impellers on two sides, the impellers transmit power through the steering gears in the rotating process, wherein a third steering bevel gear 36 is respectively arranged in two steering gears 30 closest to the wind deflector, the power is finally transmitted to the third steering bevel gear 36 through the rotation of the impellers, the third steering bevel gear 36 drives the transmission shaft 35 and the steering gear 30 on the transmission shaft 35, and the power is transmitted to the generator 4, so that power generation is achieved.

Example 4: the structure of the wind power generation device is the same as that of the embodiment 3, but the application is different, and the embodiment is that the wind power generation device is used on the sea surface to generate electricity;

as shown in fig. 9, when the wind power generating device is used on the sea surface, the wind power generating device comprises a floating device 26, a fixing pile 27 and a rope 28, the lower plate 2 of the wind power generating device is fixed on the floating device 26, the floating device 26 floats on the sea surface, one end of the floating device 26 is connected to the fixing pile 27 through the rope 28, the fixing pile 27 is fixed in the sea, the connecting end of the rope 28 and the floating device 26 is opposite to the tip end of the wind deflector 3, when wind blows, the floating device 26 rotates along the fixing pile under the traction of the rope 28 until the floating device 26 and the rope 28 keep the same wind direction, as the connecting end of the rope 28 and the floating device 26 is opposite to the tip end of the wind deflector 3, the wind direction is opposite to the tip end of the wind deflector 3, the wind deflector 3 guides the wind to two sides, the wind blows to the impellers on two sides, the impellers transmit power through gears during the rotation, the two steering gears 30 closest to the air deflector are respectively provided with a third steering bevel gear 36, force is finally transmitted to the third steering bevel gear 36 through rotation of the impeller, the third steering bevel gear 36 drives the transmission shaft 35 and the steering gears 30 on the transmission shaft 35, and the force is transmitted to the generator 4, so that power generation is realized.

the utility model discloses wind power generation set, it utilizes the impeller to convert wind-force into kinetic energy, through the design of a plurality of diverters, transmits kinetic energy on the generator, realizes wind power generation, and the diverter can alleviate the quality of whole device; the device has a simple structure, can change the size of the device according to requirements, can be applied to the sea or the land, and achieves the purpose of generating power under different environments by matching with different fixing structures.

In addition, the wind deflector is arranged to guide wind to change the wind direction into V-shaped movement, then the impellers are arranged into two rows in a V shape, the wind drives the impellers to rotate just corresponding to the wind passing through the wind deflector, and the wind energy is converted into kinetic energy; then the upper end and the lower end of each impeller are provided with a steering gear, and a steering shaft is arranged on the steering gear, so that all the impellers can synchronously rotate, and the transmission of power among the impellers is also realized; meanwhile, the third steering bevel gear and the rotating shaft are arranged at the convergence position of the V-shaped ends of the two rows of impellers, so that the kinetic energy of the impellers on two sides can be converged, and finally, the kinetic energy is transmitted to the generator through the group of steering gears, and the conversion from the kinetic energy to the electric energy is realized.

The utility model discloses in only having written out individual layer structure's power generation facility in detail, the device can superpose the multilayer in the in-service use process, and adjacent two-layer power generation facility's hypoplastron is fixed with the upper plate, and the total power generation facility that obtains like this has a plurality of generators, collection wind energy that can be more, improves the generating efficiency.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims

1. A wind power generation device characterized in that: the novel wind power generation device comprises an upper plate (1), a lower plate (2) and impellers positioned between the upper plate (1) and the lower plate (2), wherein the upper plate (1) and the lower plate (2) are arranged in parallel relatively, a plurality of impellers are arranged between the upper plate (1) and the lower plate (2), the impellers are arranged in two rows, each row of impellers are connected through a transmission mechanism to realize synchronous rotation, an included angle is formed between the planes of the two rows of impellers, an air guide plate (3) is arranged at the included angle, the impellers, closest to the air guide plate (3), of the two rows of impellers are a first power impeller (5) and a second power impeller (6), a linkage structure is arranged between the first power impeller (5) and the second power impeller (6), and a generator (4) is connected to the linkage structure.

2. Wind power plant according to claim 1, characterized in that: the impeller comprises a central shaft (7), a sleeve (8) and blades (9), wherein two ends of the central shaft (7) are respectively connected to the upper plate (1) and the lower plate (2), the sleeve (8) is fixed to the outer side of the central shaft (7), and the outer side of the sleeve (8) is provided with the blades (9).

3. A wind power plant according to claim 2, characterized in that: the transmission mechanism of each row of impellers is a plurality of gears which are meshed together and is divided into an upper gear (10) and a lower gear (12), the upper gear (10) is installed on the outer side of the upper end of the central shaft (7), one side of the upper gear (10) is abutted against the upper plate (1), an upper partition plate (11) is arranged on one side, opposite to the upper plate (1), of the upper gear (10), and the upper gear (10) is located between the upper plate (1) and the upper partition plate (11); the lower gear (12) is arranged on the outer side of the lower end of the central shaft (7), one side of the lower gear (12) is abutted against the lower plate (2), a lower partition plate (13) is arranged on the side, opposite to the lower plate (2), of the lower gear (12), and the lower gear (12) is located between the lower plate (2) and the lower partition plate (13);

an upper transition gear (14) and a lower transition gear (15) are arranged between the two adjacent central shafts (7), the upper transition gear (14) is positioned between the two adjacent upper gears (10), and the upper transition gear (14) is fixed between the upper plate (1) and the upper partition plate (11) through a short shaft (16); the lower transition gear (15) is positioned between two adjacent lower gears (12), and the lower transition gear (15) is fixed between the lower plate (2) and the lower partition plate (13) through a stub shaft (16).

4. A wind power plant according to claim 3, characterized in that: the linkage structure between the first power impeller (5) and the second power impeller (6) is a first power gear (17) and a second power gear (18) which are meshed with each other, the first power gear (17) is arranged on a central shaft (7) of the first power impeller (5), the second power gear (18) is arranged on the central shaft (7) of the second power impeller (6), and the first power gear (17) and the second power gear (18) are both arranged close to the lower gear (12) and are positioned on the side, opposite to the lower gear (12), of the lower partition plate (13);

the first power impeller (5) transmits power to the generator (4) through a first bevel gear (19) and a second bevel gear (20) which are matched, the first bevel gear (19) is installed on a central shaft (7) of the first power impeller (5), the first bevel gear (19) is meshed with the second bevel gear (20) and connected, and the generator (4) is connected with the second bevel gear (20) through a transmission shaft.

5. A wind power plant according to claim 2, characterized in that: the transmission mechanism of each row of impellers comprises a plurality of steering gears (30) which are connected together, each steering gear (30) comprises a gear box (34) and a first steering bevel gear (32) and a second steering bevel gear (33) which are positioned inside the gear box (34), and the first steering bevel gear (32) and the second steering bevel gear (33) are in meshed connection; the upper surfaces of the upper plate (1) and the lower plate (2) are respectively provided with two rows of steering gears (30) along the distribution direction of two rows of impellers, each row of steering gears (30) are connected together through a steering shaft (31), a first steering bevel gear (32) in each steering gear (30) is fixedly connected to the end part of a corresponding impeller central shaft (7), a second steering bevel gear (33) is connected to the steering shaft (31), and when the impellers rotate, the central shaft (7) and the first steering bevel gear (32) synchronously rotate and simultaneously drive the second steering bevel gear (33) to rotate;

the upper surfaces of the upper plate (1) and the lower plate (2) are respectively fixedly connected with an upper partition plate (11) and a lower partition plate (13), a steering gear (30) and a steering shaft (31) which are installed on the upper surface of the upper plate (1) are located between the upper plate (1) and the upper partition plate (11), and the steering gear (30) and the steering shaft (31) which are installed on the upper surface of the lower plate (2) are located between the lower plate (2) and the lower partition plate (13).

6. Wind power plant according to claim 5, characterized in that: the linkage structure between the first power impeller (5) and the second power impeller (6) comprises a transmission shaft (35) and third steering umbrella teeth (36), the inside of a steering gear (30) connected below the first power impeller (5) and the second power impeller (6) is respectively provided with one third steering umbrella tooth (36), the two third steering umbrella teeth (36) are respectively in tooth joint with the first steering umbrella teeth (32) in the two steering gears (30), a transmission shaft (35) is arranged between the two third steering umbrella teeth (36), when the third steering umbrella teeth (36) rotate, the transmission shaft (35) synchronously rotates, the middle part of the transmission shaft (35) is provided with one steering gear (30), and the generator (4) is connected to the steering gear (30); the first steering bevel gear (32) of the steering gear (30) is arranged on a transmission shaft (35), and the second steering bevel gear (33) is connected with the generator (4).

7. Wind power plant according to claim 4 or 6, characterized in that: and bearings (29) are arranged at the joints of the central shaft (7) and the upper plate (1), the lower plate (2), the upper partition plate (11) and the lower partition plate (13).

8. Wind power plant according to claim 1, characterized in that: the air guide plate is characterized in that the upper plate (1) and the lower plate (2) are triangular plates with the same direction, the two rows of impellers are distributed along two bevel edges of the triangular plates, the air guide plate (3) is arranged at an included angle of the two rows of impellers, the included angle of the two rows of impellers is 50-60 degrees, two sides of the air guide plate (3) are respectively parallel to the plane where the two rows of impellers are located, and the upper end and the lower end of the air guide plate (3) are respectively fixed on the upper plate (1) and the lower plate (2).

9. Wind power plant according to claim 1, characterized in that: when the wind power generation device is used on land, the wind power generation device further comprises a fixing device, the fixing device comprises an empennage (21), a base (22), a supporting shaft (23), a first supporting seat (24) and a second supporting seat (25), the first supporting seat (24) is installed on the lower surface of the upper plate (1), the second supporting seat (25) is installed on the lower surface of the lower plate (2), the positions of the first supporting seat (24) and the second supporting seat (25) correspond to each other up and down, the first supporting seat (24) and the second supporting seat (25) are connected through the supporting shaft (23) penetrating through the lower plate (2), the lower end of the supporting shaft (23) is fixed on the base (22), and bearings (29) are arranged at the connection positions of the supporting shaft (23) and the first supporting seat (24) and the second supporting seat (25); the tail wing (21) is arranged on the upper surface of the upper plate (1), arranged between two rows of impellers and distributed along the symmetrical axes of the two rows of impellers, and the tail end of the tail wing (21) extends to the outer side of the upper plate (1).

10. Wind power plant according to claim 1, characterized in that: when the wind power generation device is used on the sea surface, the wind power generation device further comprises a floating device (26), a fixing pile (27) and a rope (28), the lower plate (2) is fixed on the floating device (26), the floating device (26) floats on the water surface, one end of the floating device (26) is connected to the fixing pile (27) through the rope (28), the fixing pile (27) is fixed under the water, and the connecting end of the rope (28) and the floating device (26) is opposite to the tip end of the air deflector (3).